KR101315180B1 - Wind power generator floating on the water - Google Patents

Abstract

PURPOSE: A floating continuous wind power generator is provided to rotate on the surface of the water in the direction of the wind in order to increase generating efficiency because a blade-mounting support shaft is fixed on a ship and a ship rotates on the surface of the water in the direction of the wind by a direction indicating unit. CONSTITUTION: A floating continuous wind power generator comprises a ship (200), a direction indicating unit (210), a support shaft (230), a blade (240), and a generator (250). The support shaft is mounted on the upper part of the ship. The blade is mounted on the support shaft and is rotated by wind force. The generator generates electricity by the rotation of the blade. A capacitor stores electricity generated by the generator. The direction indicating unit is mounted on the ship and rotates the ship in the direction of the wind. The support shaft is fixed to the ship and rotates along with the ship on the surface of the water by the direction indicating unit.

Description

Wind power generator floating on the water}

The present invention relates to a floating continuous wind power generator, which is capable of converting mechanical energy generated by wind power into electrical energy by rotating according to the wind direction while floating on the surface of the water.

Common methods of power generation include hydro, thermal and nuclear.

These power generation methods require large-scale power generation facilities.

Among these, in the case of thermal power generation, a huge amount of fossil fuel must be supplied to operate a power generation facility, but the reserve of fossil fuel is limited, and pollutant emission due to the combustion of fossil fuel is also a big problem.

In the case of nuclear power generation, there are serious problems with radioactive leakage and nuclear waste disposal.

Due to these problems, there is a demand for alternative power generation methods for stable power supply while reducing the emission of pollutants.

Accordingly, solar power generation, wave power generation, tidal power generation, and wind power generation are being studied.

This power generation method uses natural power as it is, and does not emit pollutants in power generation.

Korean Patent Publication No. 10-2008-0083605 discloses a wind power generator.

1 is a longitudinal sectional view showing a conventional wind power generator.

As shown in FIG. 1, the conventional wind power generator includes a support 101; A rotation shaft (110) disposed between the support (101) and the support (101) so that both ends are rotatably installed on the support (101); Centers are fixed at predetermined intervals in the longitudinal direction of the rotary shaft 110, respectively, and the blades 111 are driven in association with the rotary shaft 110 according to the resistance of the wind; It is fixed to the inside of the support 101 is made of a wind power generator (30) for generating electricity in accordance with the rotation of the rotary shaft (110).

A plurality of blades 111 are mounted on the rotating shaft 110 to rotate together with the rotating shaft 110.

As described above, in the conventional wind power generator, a plurality of blades 111 are mounted and rotated on the rotation shaft 110 to increase the amount of power generated.

However, in the conventional wind power generator, both ends of the rotating shaft 110 are installed on the support 101 to stably support the rotating shaft 110 on which the plurality of blades 111 are mounted. ) Cannot be rotated according to the wind direction.

Therefore, the conventional wind power generator as described above has a problem that can not efficiently produce power in accordance with the change in the wind direction.

Meanwhile, the rotary shaft 110 may be rotated on one support 101 to rotate the rotary shaft 110 in which the blade 111 is mounted according to the wind direction so that the blade 111 faces the wind blowing direction. In the case of the coupling, the deflection may occur or become unstable due to the load of the rotary shaft 110 and the blade 111.

The present invention has been made to solve the above-mentioned problems, and the object of the present invention is to provide a floating continuous wind power generation apparatus that can stably support a large load and rotate according to the wind direction, thereby improving power generation efficiency and increasing power generation.

Floating continuous wind power generator of the present invention to achieve the above object, buoyancy line floating on the water surface; A support shaft mounted on an upper portion of the buoyancy line; A blade mounted to the support shaft and rotating by wind power; A generator for generating electricity by rotating the blade; A capacitor for storing electricity generated by the generator; A direction indicating unit mounted to the buoyancy line to rotate the buoyancy line according to the wind direction; It is made, including, the support shaft is fixed to the buoyancy line is rotated with the buoyancy line on the water surface by the direction indicating unit.

The support shaft may include a horizontal shaft on which the blade is mounted; A plurality of vertical shafts mounted on the buoyancy line to support the horizontal shafts; Lt; / RTI >

The support shaft is composed of a plurality, the horizontal axis is disposed parallel to each other spaced, each horizontal axis is mounted with a plurality of the blades.

The plurality of horizontal axes are disposed at different heights up and down.

The support shaft is stacked up and down to form a multilayer structure.

It is mounted to the buoyancy line further comprises an anchor to allow the buoyancy line to rotate within a certain range of the water surface.

The blade is made of a plurality of mounted in a line on the support shaft, the direction indicator is disposed inclined in the horizontal direction with the support shaft, the blade is rotated by the wind blowing in a direction inclined from the front of the blade.

Floating continuous wind power generator according to the present invention has the following effects.

The support shaft on which the blade is mounted is fixedly mounted on the buoyancy line, and the buoyancy line is rotated with the support shaft according to the wind direction by the direction indicating part on the surface of the water, so that the blade is rotated on the water surface according to the wind direction while stably supporting the blade load. It can improve the power generation efficiency and increase the power generation.

In addition, since the plurality of vertical axes stably support the horizontal axis on which the blades are mounted, the number of blades can be increased to increase the amount of power generated.

In addition, the support shaft is composed of a plurality of spaced apart parallel to each other in the upper portion of the buoyancy line, the buoyancy line is rotated in accordance with the wind direction, so that a plurality of blades mounted on each support shaft is directed in the wind blowing direction to improve the power generation efficiency You can.

In addition, the buoyancy line is equipped with an anchor to allow the buoyancy line to rotate within a certain range of the water surface, so that the buoyancy line is easy to rotate without floating along the flow of wind and water.

In addition, a plurality of blades are mounted in a line on the support shaft, the direction indicating portion is inclined in the horizontal direction with the support shaft is rotated by the wind blowing in the direction inclined from the front of the blade, so that the plurality of blades Receive a uniform air flow to maximize the use of wind energy.

1 is a longitudinal sectional view showing a conventional wind power generator,
2 is a structural view showing the side of the floating continuous wind power generator according to the first embodiment of the present invention,
3 is a plan view of the floating continuous wind power generator according to the first embodiment of the present invention,
4 is a structural diagram showing various structures of the floating continuous wind power generator according to the first embodiment of the present invention,
5 is a plan view of the floating continuous wind power generator according to the second embodiment of the present invention,

Hereinafter, the present invention will be described in more detail with reference to the accompanying drawings.

2 is a structural diagram showing the side of the floating continuous wind power generator according to the first embodiment of the present invention, Figure 3 is a plan view of the floating continuous wind power generator according to the first embodiment of the present invention, Figure 4 is Structural diagram showing various structures of the floating continuous wind power generator according to the first embodiment of the present invention.

Floating continuous wind power generator according to the first embodiment of the present invention, as shown in Figure 2 to Figure 4, buoyancy line 200, direction indicating unit 210, anchor 220, support shaft 230, blade 240, a generator 250, and a capacitor (not shown).

The buoyancy line 200 may be a small ship, raft, buoy, etc. that can be floating on the water surface.

The buoyancy line 200 may be installed in the sea, rivers, lakes, reservoirs.

In addition, the buoyancy line 200 may be installed by artificially making a puddle.

In addition, by digging a puddle in the tidal flat and the water exits after filling the tidal flat may be installed to the buoyancy line 200 to fill the puddle.

The buoyancy line 200 may be manufactured by varying its shape and size according to the place where it is installed.

As shown in FIG. 2, the support shaft 230, the blade 240, the generator 250, and the capacitor are mounted on the buoyancy line 200 to convert mechanical energy generated by wind power into electrical energy. .

The direction indicating unit 210 is mounted on the buoyancy line 200 to rotate the buoyancy line 200 according to the wind direction.

In addition, the buoyancy line 200 is mounted to the anchor 220 so that the buoyancy line 200 is rotated within a certain range of the water surface.

The direction indicating unit 210 is mounted on the buoyancy line 200 to rotate the buoyancy line 200 according to the wind direction.

That is, the direction indicating unit 210 is used in a general wind generator 250 in order to rotate the blade 240 to face in the wind blowing direction, as shown in Figure 3 the buoyancy line ( The buoyancy line 200 is rotated on the surface of the water by the wind direction.

At this time, the support shaft 230 and the blade 240 mounted on the buoyancy line 200 is rotated together.

The anchor 220 is mounted on the buoyancy line 200 to allow the buoyancy line 200 to rotate within a predetermined range of the water surface.

That is, since the buoyancy line 200 as described above can be floated by the flow or wind of the current or the river, the buoyancy line 200 is floated within a predetermined range of the water by mounting the anchor 220. It does not go and is rotated well according to the wind direction.

The support shaft 230 is fixedly mounted on the upper portion of the buoyancy line 200 to rotate together with the buoyancy line 200 on the water surface by the direction indicating unit 210.

In detail, the support shaft 230 includes a horizontal axis 231 and a vertical axis 232.

The blade 240 is rotatably mounted on the horizontal shaft 231.

The vertical axis 232 is mounted to the buoyancy line 200 to support the horizontal axis 231.

The vertical axis 232 may be configured to support the horizontal axis 231, but as shown in FIG. 2 or 3, both ends of the horizontal axis 231 are supported to more stably support the horizontal axis 231. can do.

In general, the conventional wind power generator 250 is to support the horizontal axis 231 to a single vertical axis 232 to rotate the horizontal axis 231 according to the wind direction.

That is, the horizontal axis 231 is rotatably coupled to the upper portion of the vertical axis 232.

Therefore, there is a limitation in the number, size and shape of the horizontal axis 231, the blade 240 or other structures installed on the vertical axis 232 because there is a limit to the load that can be supported by a single vertical axis (232).

However, in this embodiment, since the horizontal axis 231 on which the blade 240 is mounted is supported by the vertical axis 232 without being directly rotated and fixedly mounted to the buoyancy line 200, the buoyancy line 200 ) Rotates with the buoyancy line 200 as it rotates on the surface of the water.

Accordingly, the horizontal shaft 231 may be manufactured to be supported by two or more vertical shafts 232 as necessary, so that a plurality of structures such as the blade 240 and the generator 250 are installed on the horizontal shaft 231. It can support stably even if the load is applied.

As a result, the horizontal axis 231 is extended long and a plurality of blades 240 are mounted to increase the amount of power generated and to expect higher power generation efficiency in a limited installation space.

In addition, the large blade 240 may be installed to produce power.

The support shaft 230 is formed in plural and mounted on the buoyancy line 200.

The plurality of support shafts 230 are spaced apart in parallel to each other, and a plurality of blades 240 are mounted on each of the support shafts 230.

As shown in FIG. 4, a plurality of the support shafts 230 may be installed in the horizontal direction, or the horizontal shafts 231 may be disposed to be vertically disposed.

In this case, in order to minimize the installation space on the buoyancy line 200, it is preferable to arrange the other horizontal axis 231 on the upper side between the horizontal axis 231 disposed adjacent to the horizontal direction as shown in Figure 4 (b) Do.

In addition, as shown in Figure 4 (c), the support shaft 230 may be stacked up and down to form a multi-layer structure.

In addition, the support shaft 230 does not vertically install the horizontal axis 231 in the buoyancy line 200 as shown in FIG. 3 or 4 (a), and is transverse to the buoyancy line 200. The plurality of blades 240 may be mounted to face the buoyancy line 200 opposite to the direction in which the direction indicating unit 210 is disposed.

The support shaft 230 may be installed in various structures in addition to the structure shown in the present embodiment.

In this way, the support shaft 230 is composed of a plurality of spaced apart parallel to each other in the upper portion of the buoyancy line 200, the buoyancy line 200 is rotated in accordance with the wind direction, each of the support shaft 230 A plurality of mounted blades 240 may be directed in a direction in which the wind blows, thereby increasing power generation efficiency and improving power generation efficiency.

The blade 240 is mounted to the support shaft 230 to rotate by the wind.

In addition, the blade 240 is formed in plural and mounted in a row on the support shaft 230.

That is, a plurality of blades 240 are mounted in a row on the horizontal axis 231.

As described above, since the horizontal shaft 231 is supported at both ends by the vertical shaft 232, the horizontal shaft 231 extends the length of the horizontal shaft 231 to increase the amount of power generated while being stably supported. You can.

And the buoyancy line 200 is equipped with a generator 250 for generating electricity by the rotation of the blade 240.

The generator 250 is mounted to each of the blades 240 to generate electricity.

That is, the generator 250 receives the rotational force of the blade 240 rotated by the wind to convert mechanical energy into electrical energy.

The generator 250 may not be mounted on each of the blades 240 as in the present embodiment, but may be mounted on the support shaft 230 or the upper portion of the buoyancy line 200.

In this case, a power transmission structure capable of transmitting the rotational force of each of the blades 240 to the generator 250 is required.

The capacitor is mounted on the buoyancy line 200 and stores the electricity generated by the generator 250.

As described above, in the continuous wind power generator according to the present embodiment, the support shaft 230 on which the blade 240 is mounted is fixedly mounted to the buoyancy line 200, and the buoyancy line 200 is located above the water surface. By rotating along with the support shaft 230 according to the wind direction by the direction indicator 210, the number of the blades 240 is increased or a large blade 240 is applied to the support shaft 230 Even if the load is increased, it can stably support and rotate on the water surface according to the wind direction to improve the power generation efficiency and increase the power generation.

5 is a plan view of a floating continuous wind power generator according to a second embodiment of the present invention.

Floating continuous wind power generation apparatus according to the second embodiment will be mainly focused on the direction indicating unit is different from the direction indicating unit compared to the first embodiment.

As shown in FIG. 5, the floating continuous wind power generator according to the second embodiment of the present invention includes a buoyancy line 200, a direction indicating unit 210, an anchor 220, a support shaft 230, and a blade 240. , The generator 250 and a capacitor.

The buoyancy line 200, the anchor 220, the support shaft 230, the blade 240, the generator 250 and the capacitor are the same as in the above-described embodiment 1 bar detailed description thereof will be omitted.

As shown in FIG. 5, the direction indicating unit 210 is disposed to be inclined in the horizontal direction with the support shaft 230, that is, the horizontal shaft 231.

Accordingly, when the buoyancy line 200 is rotated by the direction indicating unit 210 according to the wind direction, the blade 240 is rotated by the wind blowing in a direction inclined from the front of the blade 240.

Therefore, the plurality of blades 240 mounted in a line on the horizontal axis 231 are rotated by the wind blowing in a direction inclined from the front of the blade 240, respectively.

On the other hand, when the blades 240 mounted in a row on the horizontal axis 231 is directed in the wind blowing direction to rotate the blades 240 disposed in the rear while the blade 240 disposed before the rotation by the wind Since the wind energy is reduced, power generation efficiency may be reduced even when a plurality of blades 240 are installed.

 In addition, an abnormal turbulent flow is generated in the wind passing while rotating the blade 240 disposed above, which makes it difficult to effectively rotate the blade 240 disposed behind.

Accordingly, in the present embodiment, a plurality of the blades 240 are mounted in a row on the support shaft 230, and the direction indicating unit 210 is disposed to be inclined in the horizontal direction with the support shaft 230. ) Is rotated by the wind blowing in a direction inclined from the front surface of the blade 240, the plurality of blades 240 receives a uniform air flow and to maximize the use of wind energy to increase the power generation and improve the power generation efficiency You can.

The direction indicating unit 210 may enable angle adjustment of the horizontal axis 231 and the direction indicating unit 210 according to the wind strength.

Floating continuous wind power generation device of the present invention is not limited to the above-described embodiment can be carried out in a variety of modifications within the scope of the technical idea of the present invention.

200: buoyancy line,
210: direction indicator,
220: anchor,
230: support shaft, 231: horizontal axis, 232: vertical axis,
240: blade,
250: generator,

Claims (7)

Buoyancy lines floating on the surface;
A support shaft mounted on an upper portion of the buoyancy line;
A blade mounted to the support shaft and rotating by wind power;
A generator for generating electricity by rotating the blade;
A capacitor for storing electricity generated by the generator;
A direction indicating unit mounted to the buoyancy line to rotate the buoyancy line according to the wind direction; , ≪ / RTI >
And the support shaft is fixedly mounted to the buoyancy line to rotate together with the buoyancy line on the water surface by the direction indicating unit. The method according to claim 1,
The support shaft,
A horizontal axis on which the blade is mounted;
A plurality of vertical shafts mounted on the buoyancy line to support the horizontal shafts; Floating continuous wind power generator, characterized in that consisting of. The method according to claim 2,
The support shaft is made of a plurality,
The horizontal axis is arranged parallel to each other spaced apart, each continuous horizontal wind turbine generator, characterized in that a plurality of the blade is mounted. The method according to claim 3,
A plurality of said horizontal axis is floating continuous wind power generator, characterized in that arranged at different heights up and down. The method according to claim 3,
The support shaft is a floating continuous wind power generator, characterized in that stacked up and down to form a multi-layer structure. The method according to claim 2,
Floating continuous wind power generation device characterized in that it further comprises an anchor mounted on the buoyancy line so that the buoyancy line is rotated within a certain range of the water surface. The method according to claim 2,
The blade is made of a plurality mounted in a line on the horizontal axis,
The direction indicating unit is disposed to be inclined in a horizontal direction with the horizontal axis,
The blade is a continuous wind power generator, characterized in that for rotating by the wind blowing in a direction inclined from the front of the blade.

Images